When Galaxies CollideWhen Galaxies Collide

When Galaxies CollideIt is not uncommon for galaxies to gravitationally interact with each other, and even collide!

When Galaxies Collide

When Galaxies Collide

When galaxies collide, the stars do not. (They’re much too far apart.) However,

Galaxies can be tidally distorted, or even torn apart. The Hubble types of the galaxies can change. The gas clouds within each galaxy can collide. The

increased density of gas can cause lots of star formation. The galaxy can produce lots of supernovae (from all the

young O and B stars).

Exactly what happens depends on the relative sizes of the galaxies, their orientation, the direction of their rotation, and their original Hubble types.

Example 1: Two Large Galaxies

Example 1: Two Large Galaxies

Example 1: Two Large Galaxies

Example 1: Two Large Galaxies

In the center of the system, large numbers of bright star clusters are being created

Example 2: The Milky Way and a Dwarf Galaxy

A small dwarf galaxy

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Example 2: The Milky Way and a Dwarf Galaxy

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Example 2: The Milky Way and a Dwarf Galaxy

View of a galaxy currently being disrupted

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Example 2: The Milky Way and a Dwarf Galaxy

Much of the Milky Way’s halo may consist of the remains of tidally disrupted galaxies.

Example 3: Two Large Galaxies

Example 3: Two Large Galaxies

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After the Encounter

Simulations show that the remains of these encounters look very much like elliptical galaxies!

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“Young” Ellipticals

A few ellipticals even show traces of past interactions

Introduction to Introduction to CosmologyCosmology

Types of UniversesIf you were to make a universe, would you give it a finite size, or make it infinite?

In a finite universe, gravity eventually takes over and causes a big collapse.

If you make it finite …

Types of UniversesIf you were to make a universe, would you give it a finite size, or make it infinite?

In an infinite universe, light would come from everywhere. The night sky would be bright! This is Olber’s paradox.

If you make it infinite …

The Cosmological ConstantIn 1918, Einstein realized the difficulty with a finite universe, and the impossibility of an infinite universe. So to keep the universe from collapsing, he postulated the existence of a Cosmological Constant (i.e., an extra anti-gravity term to counteract attraction). This is represented by .

Meanwhile … Vesto Slipher was measuring the Doppler shifts of galaxies …

The Redshifts of GalaxiesMoving Toward Us Moving Away From Us

The Hubble Law

Edwin Hubble estimated the distances to Slipher’s galaxies. He found that the larger the distance, the faster the galaxy was moving (away from us). In fact, the relationship between velocity and distance was simply

V = H DV = H Dwhere VV is velocity (km/s) DD is distance (in Mpc) HH is the Hubble Constant

The Hubble LawThe Hubble Law is not perfect. In addition to its cosmological flow, each galaxy has a peculiar (random) velocity of 300 km/s. But at large distances, the Hubble flow dwarfs this component.

Hubble’s original conclusion: H0 = 500 km/s/Mpc

The Cosmological Principle

Since we are not at the center of our Solar System, our Galaxy, or our Local Group of galaxies, it is exceedingly likely that we’re also not at the center of the universe. We therefore adopt the cosmological principle, which states that the universe (on average) must look the same to everyone, no matter where he/she/it is. In other words,

the universe is (on average) homogeneous (i.e., smooth) the universe is (on average) isotropic (no special direction)

Then why should the galaxies all be moving away from us!

The Balloon AnalogyIt is as if all galaxies exist on the surface of a balloon. The space between all the galaxies is constantly increasing.

Important Note: We are not receding from each other! The stars in the Galaxy are not receding from each other. It is only the space between galaxies that is increasing.

The Dynamic Universe

The Hubble Law solves both the problem of universal collapse and Olber’s paradox.

Since the galaxies are moving away from each other, gravity will not necessarily cause a big collapse. So a finite universe is possible.

The larger the distance, the larger the velocity. Galaxies at the other end of the universe have their light Doppler shifted out of the optical. No wonder the night sky is dark! Infinite universes are possible.

Einstein’s reaction: “The Cosmological Constant was my greatest blunder.”

An Age to the Universe

The Hubble Law implies the universe began with a Big Bang, which started the galaxies flying apart. It also implies a finite age to the universe. This age depends on two things:

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• The expansion rate of the universe. (“How fast are the galaxies flying apart?”)

• The density of the universe. (“How much is gravity slowing down the expansion?”)

An Age to the Universe

The Hubble Law implies the universe began with a Big Bang, which started the galaxies flying apart. It also implies a finite age to the universe. This age depends on two things:

• The expansion rate of the universe. (“How fast are the galaxies flying apart?”)

• The density of the universe. (“How much is gravity slowing down the expansion?”)

A Fate to the Universe

The Hubble Law also implies 3 possible fates for the universe: The universe will expand forever (an unbound or open

universe) Gravity will eventually reverse the expansion and cause

the universe to collapse into a “Big Crunch” (a bound or closed universe)

The universe is precisely balanced between open and closed (a marginally bound or flat universe)

The Shape of the UniverseAccording to Einstein, mass bends space. This means that the universe has a shape. This shape is related to the amount of matter in the universe.

Type Shape of Universe

Open Universe

Closed Universe

Flat Universe

The Age of the Universe

If there were no mass (i.e., no gravity) in the universe, the Hubble expansion would proceed at a constant speed. The age of the universe would then just be given by 1 / H0.

In a real universe with mass, gravity must have (over time) slowed the Hubble expansion. In the past, the galaxies must have been moving apart faster. The age must therefore be less than 1 / H0. For a “flat” universe, it is two-thirds of 1/ H0.

If you can measure H0, you can estimate the age of the universe!

Note that H0 = V / D, and velocities are easy to measure via the Doppler shift. So all you need to do is measure the distances to galaxies!

Next time -- the Big Bang